KR20130038756A - Communication system - Google Patents

Abstract

PURPOSE: A communication system is provided to enable a second portable terminal to use information and functions of a first portable terminal by using transmission information received from the first portable terminal. CONSTITUTION: A first portable terminal(100) comprises an electric potential measuring sensor(140), an MCU(Micro Controller Unit)(160), and a first BLE(Bluetooth Low Energy) module(120). The MCU compares an electric potential measured by the electric potential measuring sensor with a reference value. The MCU sets a part of information stored based on a comparison result as transmission information. The first BLE(Bluetooth Low Energy) module transmits the transmission information. A second portable terminal includes a second BLE module. The second BLE module receives the transmission information by connecting to the first BLE module. [Reference numerals] (120) First BLE module; (130) First Wi-Fi module; (140,240) Electric potential measurement sensor; (170,270) Battery; (220) Second BLE module; (230) Second Wi-Fi module;

Description

{COMMUNICATION SYSTEM}

The present invention relates to a communication system of mobile terminals that are formed to enable wireless communication with each other.

A mobile terminal is a portable electronic device that is portable and has one or more functions of voice and video call function, information input / output function, and data storing function.

As the functions are diversified, the mobile terminal is implemented in the form of a multimedia player having complex functions such as taking a picture or a video, playing a music or a video file, and receiving a game or a broadcast.

In order to supply power, a mobile terminal is equipped with a battery. The battery is rechargable and maintains a constant pressure above a certain amount. However, when the battery is discharged and falls below a certain amount (for example, 10%), the voltage begins to decrease and shortly afterwards, it is completely discharged.

When the battery is completely discharged, the AP (application processor) for driving and controlling the OS, applications, etc. required for the mobile terminal is deactivated. In this case, since the AP cannot be activated until the battery is charged, the function / information of the mobile terminal cannot be used.

An object of the present invention is to propose a communication system that can use the function / information of the mobile terminal even when the battery is discharged.

In order to achieve the above object of the present invention, a communication system according to an embodiment of the present invention includes a first and a second mobile terminal is formed to enable wireless communication with each other, the first mobile terminal is a potential of the battery A microcontroller unit configured to detect a potential, and a potential measured by the potential measuring sensor, to compare the potential measured with the reference value and to set a part of previously stored information as transmission information based on a comparison result; And a first BLE module configured to transmit transmission information, and the second mobile terminal includes a second BLE module connected to the first BLE module to receive the transmission information.

According to an example related to the present invention, the MCU is configured to periodically set a portion of the pre-stored information as the transmission information.

According to another example related to the present invention, when the measured potential is lower than the reference value, the MCU is configured to set a portion of the previously stored information as the transmission information.

According to another example related to the present invention, the MCU further includes a non-volatile memory (NVM), and the transmission information is stored in the non-volatile memory.

According to another example related to the present invention, the transmission information may be information used at a time point adjacent to a time point when the measured potential is lower than the reference value.

According to another example related to the present invention, the first mobile terminal further includes a memory in which the pre-stored information is recorded, and the transmission information includes latest information accessed in the memory.

According to another example related to the present invention, the transmission information may be the latest information used in the first mobile terminal.

According to another example related to the present invention, the second BLE module is configured to transmit a connection request signal to the first BLE module, and the first BLE module is connected to the second BLE module upon receiving the connection request signal. And is configured to transmit the transmission information. The transmission information may include media information executed in the first mobile terminal, and the second mobile terminal may be configured to execute media corresponding to the media information by using the received transmission information.

According to another example related to the present invention, the second mobile terminal is configured to generate an application including the transmission information by using the received transmission information.

According to another example related to the present invention, the second BLE module is configured to transmit a connection request signal to the first BLE module, and the MCU moves the first movement when the first BLE module receives the connection request signal. Control to output sound from the terminal.

According to the present invention having the above configuration, the MCU of the first mobile terminal sets a portion of pre-stored information as transmission information based on a result of comparing the measured potential with a reference value, and the first BLE module transmits the transmission information. The second BLE module of the second mobile terminal is connected to the first BLE module to receive the transmission information. Therefore, even when the battery of the first mobile terminal is discharged and the AP is deactivated, the second mobile terminal can use the function / information of the first mobile terminal by using the transmission information received from the first mobile terminal.

1 is a conceptual diagram of a communication system according to an embodiment of the present invention, in which first and second mobile terminals wirelessly communicate with each other through first and second BLE modules.
FIG. 2 sets transmission information based on a comparison result of the potential measured by the first mobile terminal shown in FIG. 1 and a reference value, and transmits the information to the second mobile terminal so that the second mobile terminal functions / functions of the first mobile terminal. Flowchart showing the process of using information.
3A through 5 illustrate that when the battery of the first mobile terminal of FIG. 1 is discharged and the AP is deactivated, the second mobile terminal uses the function / information of the first mobile terminal by using transmission information received from the first mobile terminal. Conceptual diagrams showing an embodiment.

EMBODIMENT OF THE INVENTION Hereinafter, the communication system which concerns on this invention is demonstrated in detail with reference to drawings.

The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role.

In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations. As used herein, the singular forms "a", "an" and "the" include plural forms unless the context clearly indicates otherwise.

1 is a communication system 10 according to an embodiment of the present invention, wherein the first and second mobile terminals 100 and 200 wirelessly communicate with each other through the first and second BLE modules 120 and 220. The conceptual diagram shown.

Hereinafter, configurations of the first mobile terminal 100 described may be provided in the same or similarly to the second mobile terminal 200. Configurations that are the same as or similar to those of the first mobile terminal 100 are given the same and similar reference numerals, and the description thereof is replaced with the description of the first mobile terminal 100.

Referring to FIG. 1, the communication system 10 includes a first mobile terminal 100 and a second mobile terminal 200. The first and second mobile terminals 100 and 200 are mobile phones, smart phones, laptop computers, tablet PCs, digital broadcasting terminals, PDAs (Personal Digital Assistants), and PMPs (Portable). Multimedia Player), E-book, Navigation, and the like.

The first mobile terminal 100 includes a BLE communication system for transmitting the transmission information 101 to the second mobile terminal 200 when the battery 170 is discharged and the AP 110 is deactivated. The BLE communication system includes a first Bluetooth low energy (BLE) module 120, a potential measurement sensor 140, and a micro controller unit (MCU) 160.

An application processor (AP) 110 is configured to drive and control an OS, an application, etc. required for the first mobile terminal 100. AP 110 includes one or more cores (CPUs), memory, display system / controller, multimedia encoding / decoding codec, 2D / 3D accelerator engine, image signal processor (ISP), camera, audio, modem, multiple high speed / low speed serial It may be implemented as a system-on-chip including at least one of / parallel connection interface.

Inside the first mobile terminal 100, a battery 170 for supplying power to the first mobile terminal 100 is embedded or detachably mounted. The battery 170 is configured to be chargeable, and the positive pressure is maintained at a predetermined level or more. However, when the battery 170 is discharged and falls below a certain amount (for example, 10%), the voltage begins to decrease and shortly afterwards, it is completely discharged.

When the battery 170 is completely discharged, the AP 110 for driving and controlling the OS, applications, etc. required for the first mobile terminal 100 is deactivated. In this case, since the AP 110 cannot be activated until the battery 170 is charged, the function / information of the first mobile terminal 100 cannot be used.

The PMIC 150 is configured to control a power supply for each component including the AP 110. For example, when the PMIC 150 compares the potential of the battery 170 measured by the potential measuring sensor 140 with a reference value, and the remaining amount of the battery 170 is insufficient, the PMIC 150 supplies power to the AP 110. This prevents malfunction due to low current.

The PMIC 150 is configured to supply a quiescent current to the MCU 160, the first BLE module 120, and the like to drive the BLE communication system. The reason why the BLE communication system can be maintained for a long time even after the AP 110 is deactivated is due to the minimum current generated from the battery 170, that is, the quiescent current.

The MCU 160 compares the electric potential measured by the electric potential measuring sensor 140 with a reference value, and sets a part of previously stored information as the transmission information 101 based on the comparison result. The MCU 160 may be configured as an example of a controller that controls overall operations related to the BLE communication system.

The pre-stored information includes an application program, data, execution information, and the like, and is stored in a memory. The transmission information 101 includes at least a part of previously stored information. The transmission information 101 may include, for example, media information such as a video URL path, a playback position, user setting information, or call related information such as a recent call list or a frequently used telephone number.

The MCU 160 is connected to the second mobile terminal 200 and monitors the connection request signal 201 transmitted from the second BLE module 220 to perform wireless communication. When the MCU 160 receives the connection request signal 201 and determines that it is valid (if it is determined to correspond to itself), the MCU 160 transmits the transmission information 101 through the first BLE module 120.

The first Bluetooth low energy (BLE) module 120 is configured to perform wireless communication with the second mobile terminal 200 through the second BLE module 220. The first BLE module 120 may include a BT (Bluetooth) device having a BLE function so as to consume the minimum power, and may be implemented as a dongle easily detachable as needed. Since the BT device 221 having the BLE function consumes only a portion (eg, 1 to 5 percent) of power consumed by the general BT device, the BT device 221 may communicate with the second BLE module 220 with minimal power.

BLE proposes a new low-power Bluetooth standard by improving the power consumption of the existing Bluetooth while maintaining the stability and security of the advantages of Bluetooth. BLE separates a data channel and a broadcasting channel. The first BLE module 120 is configured to transmit the transmission information 101 through at least one of 37, 38, and 39, which are transmission channels, by using the feature of the BLE.

The second mobile terminal 200 is configured to request the first mobile terminal 100 to connect with the second mobile terminal 200. The second mobile terminal 200 has a protocol for wireless communication with the first mobile terminal 100.

The AP 210 or the MCU 260 included in the second mobile terminal 200 is configured to generate a connection request signal 201 to be transmitted to the first mobile terminal 100, and the second BLE module 220 is configured to generate the connection request signal 201. The connection request signal 201 is configured to transmit to the first mobile terminal 100. The second BLE module 220 may include a BT device having a BLE function so as to consume the minimum power, such as the first BLE module 120, it may be implemented as a detachable dongle as needed.

The second mobile terminal 200 includes a memory in which a DB (DataBase) for connecting and pairing the first mobile terminal 100 and the second mobile terminal 200 is stored. The DB may include, for example, a BDADDR (Bluetooth Device ADDRess), a PIN code (Personal Identification Number), or the like of the second mobile terminal 200. Pairing of the first mobile terminal 100 and the second mobile terminal 200 is performed based on an identification code (eg, BDADDR, PIN code, etc.) of the second mobile terminal 200.

The BDADDR may include network addresses of devices having a BT function, such as the second mobile terminal 200. For example, the BDADDR may consist of a unique number (eg, 48 bits) used to designate a particular device for connection and pairing. In addition, the PIN code may be composed of a four-digit personal ID code based on the serial number and personal setting password of the second mobile terminal 200.

Hereinafter, the communication system 10 that can use at least some of the functions of the first mobile terminal 100 even when the battery 170 of the first mobile terminal 100 is discharged will be described in more detail.

FIG. 2 sets transmission information 101 based on a result of comparing the potential measured by the first mobile terminal 100 and the reference value shown in FIG. 1, and transmits the same to the second mobile terminal 200 to transmit the second movement. The flowchart illustrates a process in which the terminal 200 uses the functions / information of the first mobile terminal 100.

Referring to FIG. 2, when the battery 170 is discharged and the AP 110 is inactivated, the first mobile terminal 100 transmits a BLE communication system for transmitting the transmission information 101 to the second mobile terminal 200. Equipped.

For example, the battery 170 maintains a constant voltage of 3.7 V above a certain residual amount (10%). However, when the battery 170 is discharged and the remaining amount falls below 10%, the potential starts to decrease, and when the voltage reaches 3.3V (Cut), the PMIC 150 cuts off the power supplied to the AP 110 and the AP 110. ) Will be disabled.

However, the BLE communication system may receive a quiescent current from the PMIC 150 and thus may be maintained for a long time even after the AP 110 is deactivated. For example, unless the battery 170 is removed from the first mobile terminal 100, the BLE communication system may operate to transmit the transmission information to the second mobile terminal 200 up to 1.8V.

The first mobile terminal 100 compares the electric potential measured by the electric potential measuring sensor 140 with a reference value, and sets a part of previously stored information as the transmission information 101 based on the comparison result.

The MCU 160 is configured to set a portion of information previously stored in a memory or the like as the transmission information 101 when the measured potential drops to a reference value, for example, 3.7V or less. That is, before the AP 110 is deactivated to 3.3V, a part of prestored information accessible through the AP 110 is extracted and set as transmission information 101, and the first BLE module 120 is used to extract the information. The concept of transmitting the transmission information 101 to the second mobile terminal 200.

The transmission information 101 may be configured to be periodically set from a time point when the potential of the battery 170 drops below 3.7V. The transmission information 101 may be cumulative or may be formed so that the recently set transmission information 101 replaces the previously set transmission information 101. For example, the call related information may be sequentially recorded as the transmission information 101, and the media information may be configured to maintain only the recently set transmission information 101.

Apart from the transmission information 101 being set based on the result of comparing the measured potential with the reference value, the MCU 160 may be configured to periodically set a portion of previously stored information as the transmission information. This takes into account an unexpected situation that occurs in the battery 170 such as the potential of the battery 170 drops sharply.

The MCU 160 may further include a nonvolatile memory (NVM), and the transmission information 101 may be stored in the nonvolatile memory. Nonvolatile memory is suitable for BLE communication system because it has all the advantages of ROM that input information is not erased even if power is not supplied.

The first BLE module 120 transmits the set transmission information 101, and the second BLE module 220 is configured to receive the transmission information 101. The second mobile terminal 200 is formed to use the function / information of the first mobile terminal 100 through the transmission information 101.

3A through 5 illustrate that when the battery 170 of the first mobile terminal 100 of FIG. 1 is discharged and the AP 110 is deactivated, the second mobile terminal 200 is received from the first mobile terminal 100. The conceptual diagrams show an embodiment of using the function / information of the first mobile terminal 100 using the transmission information 101.

Referring to FIG. 3A, the first mobile terminal 100 outputs an image through the display unit 180. For example, a video may be streamed to the display unit 180 through the first Wi-Fi module 130 (see FIG. 1).

When the battery 170 is discharged and falls below a predetermined remaining amount, the display 180 may output an alarm display 181 indicating that the remaining amount of the battery 170 is low. In this case, the MCU 160 sets media information such as a video URL path, a playback position, user setting information, and the like as the transmission information 101, and periodically provides time-dependent information such as a playback position among the transmission information 101. Will be updated. That is, the transmission information 101 may include information used at a time point adjacent to a time point when the measured potential becomes lower than the reference value.

The AP 210 or the MCU 260 included in the second mobile terminal 200 is configured to generate a connection request signal 201 to be transmitted to the first mobile terminal 100, and the second BLE module 220 is configured to generate the connection request signal 201. The connection request signal 201 is configured to transmit to the first mobile terminal 100. The connection request signal 201 may include a signal for requesting the transmission information 101.

Referring to FIG. 3B, the AP 110 of the first mobile terminal 100 is inactivated by discharging the battery 170 and video streaming is stopped. However, the BLE communication system is provided with a quiescent current to enable wireless communication with the second terminal 200.

When the first BLE module 120 receives the connection request signal 201 transmitted from the second BLE module 220, and the MCU 160 determines that the connection request signal 201 is valid, the first BLE module 120 receives the connection request signal 201. The transmission information 101 is transmitted through the 120. The connection and pairing may be performed based on the identification code (eg, BDADDR, PIN code, etc.) of the second mobile terminal 200 described above.

The second mobile terminal 200 may be formed to execute the media corresponding to the media information by using the received transmission information 101. In detail, the second mobile terminal 200 may output continuous video streaming to the display unit 280 by using the video URL path, the playback position, and the user setting information included in the transmission information 101.

Referring to FIG. 4A, call-related information is stored in a memory of the first mobile terminal 100. The call related information may include a contact, a recent call list, and a frequently used phone number.

When the battery 170 is discharged and falls below a predetermined remaining amount, the display 180 may output an alarm display 181 indicating that the remaining amount of the battery 170 is low. In this case, the MCU 160 sets at least some of the call-related information as the transmission information 101 and periodically updates time dependent information such as a recent call list among the transmission information 101. That is, the transmission information 101 may include latest information accessed in the memory.

The AP 210 or the MCU 260 included in the second mobile terminal 200 is configured to generate a connection request signal 201 to be transmitted to the first mobile terminal 100, and the second BLE module 220 is configured to generate the connection request signal 201. The connection request signal 201 is configured to transmit to the first mobile terminal 100. The connection request signal 201 may include a signal for requesting the transmission information 101.

Referring to FIG. 4B, the AP 110 of the first mobile terminal 100 is inactivated by discharging the battery 170 and is no longer able to talk. However, the BLE communication system is provided with a quiescent current to enable wireless communication with the second terminal 200.

When the first BLE module 120 receives the connection request signal 201 transmitted from the second BLE module 220, and the MCU 160 determines that the connection request signal 201 is valid, the first BLE module 120 receives the connection request signal 201. The transmission information 101 is transmitted through the 120. The connection and pairing may be performed based on the identification code (eg, BDADDR, PIN code, etc.) of the second mobile terminal 200 described above.

The second mobile terminal 200 may store the received transmission information 101 in a storage space such as a RAM or an inactive memory that is connected to the AP 210 or the MCU 260. The second mobile terminal 200 may generate an application 282 including the transmission information 101 using the received transmission information 101. The application 282 may be displayed as a specific icon on a standby screen.

According to the above embodiment, even if the AP 110 of the first mobile terminal 100 is turned off, the user may make a call through the second mobile terminal 200 by transmitting call related information to the second mobile terminal 200. have.

Referring to FIG. 5, in a daily life, a user may not grasp the whereabouts of the first mobile terminal 100. When the AP 110 is activated, the call is made to the first mobile terminal 100 to determine its location through a bell, vibration, and video output. However, the operation cannot be performed when the AP 110 is deactivated.

In this case, the second BLE module 220 may transmit a connection request signal 201 to the first BLE module 120. When the first BLE module 120 receives the connection request signal 201, the MCU 160 controls the driving of the sound output module 190 to output sound from the first mobile terminal 100. The MCU 160 may control the driving of the lamp module (not shown) that is driven at a low power, such as LED, as well as the sound output, so that the first mobile terminal 100 may emit light.

According to the present embodiment, an alarm output such as sound output or light emission is possible even when the AP 110 of the first mobile terminal 100 is inactivated, and the user can output the first mobile terminal 100 through the alarm output. ) Material can be easily grasped.

The above-described communication system is not limited to the configuration and method of the embodiments described above, but the embodiments may be configured by selectively combining all or some of the embodiments so that various modifications can be made.

Claims (10)

A first mobile terminal and a second mobile terminal configured to communicate with each other wirelessly;
The first mobile terminal,
A potential measuring sensor configured to detect a potential of the battery;
A microcontroller unit (MCU) configured to compare the electric potential measured by the electric potential measuring sensor with a reference value and set a part of previously stored information as transmission information based on the comparison result; And
A first Bluetooth low energy (BLE) module configured to transmit the transmission information,
And the second mobile terminal is connected to the first BLE module and comprises a second BLE module configured to receive the transmission information. The method of claim 1,
The MCU is configured to periodically set a portion of the pre-stored information as the transmission information. The method of claim 1,
The MCU is configured to set a part of the pre-stored information as the transmission information when the measured potential is lower than the reference value. The method of claim 1,
The MCU further includes a non-volatile memory (NVM, Non-Volatile Memory),
The transmission information is stored in the non-volatile memory. The method of claim 1,
And wherein the transmission information is information used at a time point adjacent to a time point when the measured potential becomes lower than the reference value. The method of claim 1,
The first mobile terminal further includes a memory in which the pre-stored information is recorded.
The transmission information comprises the latest information accessed in the memory. The method of claim 1,
The second BLE module is configured to transmit a connection request signal to the first BLE module,
The first BLE module is connected to the second BLE module when receiving the connection request signal is configured to transmit the transmission information. 8. The method of claim 7,
The transmission information includes media information executed in the first mobile terminal,
And the second mobile terminal is configured to execute the media corresponding to the media information by using the received transmission information. The method of claim 1,
And the second mobile terminal is configured to generate an application including the transmission information by using the received transmission information. The method of claim 1,
The second BLE module is configured to transmit a connection request signal to the first BLE module,
The MCU controls a first BLE module to output sound from the first mobile terminal when the first BLE module receives the connection request signal.

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